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Main Authors: Lambertson, Evan, Bashirova, Dayana, Hunter, Kye E., Hansen, Benhardt, Zuehlsdorff, Tim J.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2406.17994
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author Lambertson, Evan
Bashirova, Dayana
Hunter, Kye E.
Hansen, Benhardt
Zuehlsdorff, Tim J.
author_facet Lambertson, Evan
Bashirova, Dayana
Hunter, Kye E.
Hansen, Benhardt
Zuehlsdorff, Tim J.
contents We compare two recently developed strategies, implemented in open source software packages, for computing linear optical spectra in condensed phase environments in the presence of nonadiabatic effects. Both approaches rely on computing excitation energy and transition dipole fluctuations along molecular dynamics (MD) trajectories, treating molecular and environmental degrees of freedom on the same footing. Spectra are then generated in two ways: In the recently developed Gaussian Non-Condon Theory (GNCT), the linear response functions are computed in terms of independent adiabatic excited states, with non-Condon effects described through spectral densities of transition dipole fluctuations. For strongly coupled excited states, we instead parameterize a linear vibronic coupling (LVC) Hamiltonian directly from spectral densities of energy fluctuations and diabatic couplings computed along the MD trajectory. The optical spectrum is then calculated using powerful, numerically exact tensor-network approaches. Both the electronic structure calculations to sample system fluctuations and the quantum dynamics simulations using tensor-network methods are carried out on graphics processing units (GPUs), enabling rapid calculations on complex condensed phase systems. We assess the performance of the approaches using model systems in the presence of a conical intersection (CI), and the pyrazine molecule in different solvent environments.
format Preprint
id arxiv_https___arxiv_org_abs_2406_17994
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Computing linear optical spectra in the presence of nonadiabatic effects on Graphics Processing Units using molecular dynamics and tensor-network approaches
Lambertson, Evan
Bashirova, Dayana
Hunter, Kye E.
Hansen, Benhardt
Zuehlsdorff, Tim J.
Chemical Physics
We compare two recently developed strategies, implemented in open source software packages, for computing linear optical spectra in condensed phase environments in the presence of nonadiabatic effects. Both approaches rely on computing excitation energy and transition dipole fluctuations along molecular dynamics (MD) trajectories, treating molecular and environmental degrees of freedom on the same footing. Spectra are then generated in two ways: In the recently developed Gaussian Non-Condon Theory (GNCT), the linear response functions are computed in terms of independent adiabatic excited states, with non-Condon effects described through spectral densities of transition dipole fluctuations. For strongly coupled excited states, we instead parameterize a linear vibronic coupling (LVC) Hamiltonian directly from spectral densities of energy fluctuations and diabatic couplings computed along the MD trajectory. The optical spectrum is then calculated using powerful, numerically exact tensor-network approaches. Both the electronic structure calculations to sample system fluctuations and the quantum dynamics simulations using tensor-network methods are carried out on graphics processing units (GPUs), enabling rapid calculations on complex condensed phase systems. We assess the performance of the approaches using model systems in the presence of a conical intersection (CI), and the pyrazine molecule in different solvent environments.
title Computing linear optical spectra in the presence of nonadiabatic effects on Graphics Processing Units using molecular dynamics and tensor-network approaches
topic Chemical Physics
url https://arxiv.org/abs/2406.17994